1 Assignment

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Accused Products

Abstract

Methods and apparatuses for calculating and transmitting medication dosage or bolus information are provided. A blood glucose meter receives a test strip with a sample of the user's blood and measures the user's blood glucose level with a sensor. The meter then calculates a bolus amount that is transmitted to a medication infusion pump using a radio frequency transmitter or transceiver. The infusion pump receives the bolus amount data and then delivers a bolus of medication to the user based on the calculated bolus estimate. The meter may also transmit commands to, and be used to remotely control, the infusion pump.

2. The system of claim 1, wherein the physiological monitoring device is adapted to be carried by the user and the medication infusion device is adapted to be carried by the user.

3. The system of claim 2, wherein the infusion device processor causes the drive mechanism to infuse the fluid in accordance with the first set of data automatically after receipt of the first set of data by the infusion device communication circuit.

4. The system of claim 2, wherein the physiological monitoring device is a blood glucose test strip monitor, and wherein the medication infusion device is an insulin infusion pump.

5. The system of claim 2, wherein the monitoring device communication circuit includes one of a transmitter and a transceiver, and wherein the infusion device communication circuit includes one of a receiver and a transceiver.

6. The system of claim 2, wherein the monitoring device further comprises an indicator coupled to the monitoring device processor and adapted to provide a notification of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

7. The system of claim 6 wherein the indicator includes at least one of a vibration alarm, a sound generation device, a panel adapted to display text, and a LED.

8. The system of claim 2, wherein the monitoring device further comprises an indicator coupled to the monitoring device processor and adapted to provide a notification of the completion of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

9. The system of claim 2 wherein the monitoring device further comprises a user input device for inputting a command and wherein the monitoring device communication circuit transmits the first set of data in response to the command from the input device.

10. The system of claim 2 wherein the monitoring device processor is further adapted to:

determine a first amount of time that has elapsed since the sensor provided the output signal; and

cause the monitoring device communication circuit to transmit the first set of data if the first amount of time does not exceed a predetermined amount of time.

11. The system of claim 10 wherein the monitoring device further comprises a user input device for inputting a command and wherein the predetermined amount of time is established in response to the command from the input device.

12. The system of claim 2 wherein the monitoring device further comprises:

an indicator coupled to the monitoring device processor and adapted to provide a display of the amount of the fluid; and

a user input device for inputting commands;

wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the first set of data in response to a first command from the input device.

13. The system of claim 12 wherein the monitoring device further comprises a monitoring device memory coupled to the monitoring device processor and adapted to store at least two fluid infusion parameters, and wherein the monitoring device processor is further adapted to:

retrieve one of the at least two fluid infusion parameters from the memory in response to a second command from the input device associated with a selection by the user of the one of the at least two fluid infusion parameters; and

cause the monitoring device communication circuit to transmit the one of the at least two fluid infusion parameters.

14. The system of claim 2 wherein the infusion device further comprises:

an indicator coupled to the infusion device processor and adapted to provide a display of the amount of the fluid; and

a user input device for inputting a command;

wherein the infusion device processor is further adapted to cause the drive mechanism to infuse the fluid into the body of the user in accordance with the first set of data in response to the command from the input device.

15. The system of claim 2 wherein the infusion device further comprises:

an indicator coupled to the infusion device processor and adapted to provide a display of the amount of the fluid;

a user input device for inputting commands; and

an infusion device memory coupled to the infusion device processor and adapted to store at least two fluid infusion parameters;

wherein the infusion device processor is further adapted to;

retrieve one of the at least two fluid infusion parameters from the memory in response to a command from the input device associated with a selection by the user of the one of the at least two fluid infusion parameters; and

cause the drive mechanism to infuse the fluid into the body of the user in accordance with the one of the at least two fluid infusion parameters.

16. The system of claim 2 wherein the monitoring device further comprises a monitoring device memory coupled to the monitoring device processor and adapted to store a first identification value associated with the identity of the infusion device, wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the first identification value;

wherein the infusion device communication circuit is further adapted to receive the first identification value; and

wherein the infusion device processor is further adapted to compare the first identification value with a stored identification value and to cause the drive mechanism to infuse the fluid into the body of the user in accordance with the first set of data if the first identification value is equal to the stored identification value.

17. The system of claim 2, wherein the monitoring device further comprises a monitoring device clock circuit adapted to provide a monitoring device date and time;

wherein the infusion device further comprises an infusion device clock circuit adapted to provide an infusion device date and time;

wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the monitoring device date and time;

wherein the infusion device communication circuit is further adapted to receive the monitoring device date and time; and

wherein the infusion device processor is further adapted to alter the infusion device date and time to be equal to the monitoring device date and time.

18. The system of claim 2, wherein the monitoring device further comprises a monitoring device clock circuit adapted to provide a monitoring device date and time;

wherein the infusion device further comprises an infusion device clock circuit adapted to provide an infusion device date and time;

wherein the infusion device processor is further adapted to cause the infusion device communication circuit to transmit the infusion device date and time;

wherein the monitoring device communication circuit is further adapted to receive the infusion device date and time; and

wherein the monitoring device processor is further adapted to alter the monitoring device date and time to be equal to the infusion device date and time.

19. The system of claim 2, wherein the monitoring device further comprises a user input device for inputting a first command and a second command, wherein the monitoring device processor is further adapted to:

receive the first and the second commands; and

cause the monitoring device communication circuit to discontinue transmissions in response to the first command and to resume transmissions in response to the second command; and

wherein the monitoring device processor is adapted to cause the monitoring device communication circuit to transmit the first set of data after receipt of the second command.

20. The system of claim 2 wherein the monitoring device further comprises:

a user input device for inputting a command; and

a memory coupled to the monitoring device processor;

wherein the monitoring device processor is further adapted to;

cause the memory to store a value associated with a duration of time established in response to the command from the input device; and

cause the monitoring device communication circuit to discontinue transmissions until the duration of time has elapsed; and

wherein the monitoring device processor is adapted to cause the monitoring device communication circuit to transmit the first set of data after the duration of time has elapsed.

21. The system of claim 2 wherein the monitoring device further comprises:

a user input device for inputting a command; and

a memory coupled to the monitoring device processor;

wherein the monitoring device processor is further adapted to;

cause the memory to store a value associated with a date and time established in response to the command from the input device; and

cause the monitoring device communication circuit to discontinue transmissions until the date and time have arrived;

wherein the monitoring device processor is adapted to cause the monitoring device communication circuit to transmit the first set of data after the date and time have arrived.

22. The system of claim 2 wherein the infusion device further comprises a user input device for inputting commands, wherein the infusion device processor is further adapted to cause the infusion device communication circuit to transmit a first command from the input device and a second command from the input device;

wherein the monitoring device communication circuit is further adapted to receive the first command and the second command;

wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to discontinue transmissions in response to the first command and to resume transmissions in response to the second command; and

wherein the monitoring device processor is adapted to cause the monitoring device communication circuit to transmit the first set of data after receipt by the monitoring device communication circuit of the second command.

23. The system of claim 2 wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit a first command repeatedly for a plurality of transmissions;

wherein the infusion device communication circuit is further adapted to receive the first command; and

wherein the infusion device processor is further adapted to;

cause power to the infusion device communication circuit to be cycled whereby the power is removed from the infusion device communication circuit for a first time period and is restored to the infusion device communication circuit for a second time period; and

cause the power to the infusion device communication circuit to be restored and the power cycling to be discontinued if the first command has been received.

24. The system of claim 23 wherein the infusion device processor is further adapted to resume the cycling of the power to the infusion device communication circuit after receipt of the first set of data following the receipt of the first command.

25. The system of claim 23 wherein the infusion device processor is further adapted to resume the cycling of the power to the infusion device communication circuit after a predetermined period of time has elapsed after receipt of the first set of data following the receipt of the first command.

26. The system of claim 23 wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit a second command after completion of the transmission of the first set of data;

wherein the infusion device communication circuit is further adapted to receive the second command; and

wherein the infusion device processor is further adapted to resume the cycling of the power to the infusion device communication circuit if the second command has been received.

27. The system of claim 2 wherein the first set of data is further indicative of at least one of a medication delivery profile, a counter value, an elapsed time since the output signal was provided, an identification value associated with the identification of the infusion device, and a date and time of transmission of the first set of data.

28. The system of claim 2 wherein the monitoring device further comprises a user input device for inputting a command, wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the command from the input device;

wherein the infusion device communication circuit is adapted to receive the command; and

wherein the infusion device processor is adapted to control the infusion device in accordance with the command.

29. The system of claim 28 wherein the control of the infusion device comprises one of a medication delivery start time, a medication delivery profile, a medication delivery rate, a medication delivery amount, a cessation of a medication delivery, an activation of an alarm, a cessation of an alarm, a display of a text message, and a download of data.

30. The system of claim 28 wherein the user input device comprises one of a button, a touch screen, a voice-activated device, and a menu structure shown on a display panel that is navigated by a keypad.

31. The system of claim 2 wherein the monitoring device further comprises a user input device for inputting a plurality of commands during a time period, said plurality of commands comprising a programming session, wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the plurality of commands if the time period has elapsed;

wherein the infusion device communication circuit is further adapted to receive the plurality of commands; and

wherein the infusion device processor is further adapted to control the infusion device in accordance with the plurality of commands.

32. The system of claim 2 wherein the monitoring device further comprises a user input device for inputting a plurality of commands corresponding to a programming session and for inputting a completion command corresponding to a completion of the programming session, and wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the plurality of commands if the completion command from the input device has been inputted;

wherein the infusion device communication circuit is further adapted to receive the plurality of commands; and

wherein the infusion device processor is further adapted to control the infusion device in accordance with the plurality of commands.

33. The system of claim 2 wherein the monitoring device further comprises a user input device for inputting a plurality of commands corresponding to a programming session, wherein the monitoring device processor is further adapted to determine a calculated time period having a beginning time and an ending time, the beginning time corresponding to the entry of one of the plurality of commands, and the ending time corresponding to the earlier of a first event and a second event, the first event being the entry of a subsequent one of the plurality of commands, and the second event being the elapse of a predetermined amount of time;

and wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the plurality of commands if the calculated time period exceeds the predetermined amount of time;

wherein the infusion device communication circuit is further adapted to receive the plurality of commands; and

wherein the infusion device processor is further adapted to control the infusion device in accordance with the plurality of commands.

34. The system of claim 2 wherein the monitoring device further comprises an indicator coupled to the monitoring device processor, wherein the infusion device processor is further adapted to cause the infusion device communication circuit to transmit a second set of data corresponding to an infusion device status;

wherein the monitoring device communication circuit is further adapted to receive the second set of data; and

wherein the monitoring device processor is further adapted to cause the indicator to display the infusion device status in accordance with the second set of data.

35. A medication infusion device for infusing a fluid into a body of a user and adapted for communications with a physiological monitoring device adapted to provide an output signal as a function of a concentration of an analyte in the user, calculate an amount of the fluid to be infused into the user's body based upon the output signal, and transmit a first set of data indicative of the amount of the fluid to be infused, the medication infusion device comprising:

a housing adapted to be carried by the user;

an infusion device processor enclosed within the housing;

a drive mechanism coupled to the infusion device processor and adapted to infuse the fluid into the body of the user; and

an infusion device communication circuit coupled to the infusion device processor and adapted to receive the first set of data from the monitoring device;

wherein the infusion device processor is adapted to cause the drive mechanism to infuse the fluid into the body of the user in accordance with the first set of data.

36. The infusion device of claim 35, wherein the infusion device processor causes the drive mechanism to infuse the fluid in accordance with the first set of data automatically after receipt of the first set of data by the infusion device communication circuit.

37. The infusion device of claim 35, wherein the physiological monitoring device is a blood glucose test strip monitor, and wherein the medication infusion device is an insulin infusion pump.

38. The infusion device of claim 37, wherein the infusion device communication circuit includes one of a receiver and a transceiver.

39. The infusion device of claim 35, wherein the monitoring device is further adapted to transmit a command selected by the user, wherein the infusion device communication circuit is further adapted to receive the command;

and wherein the infusion device processor is further adapted to control the infusion device in accordance with the command.

40. The infusion device of claim 39 wherein the control of the infusion device comprises one of a medication delivery start time, a medication delivery profile, a medication delivery rate, a medication delivery amount, a cessation of a medication delivery, an activation of an alarm, a cessation of an alarm, a display of a text message, and a download of data.

41. A physiological monitoring device adapted for communications with a medication infusion device for infusing a fluid into a body of a user, the physiological monitoring device comprising:

a housing adapted to be carried by the user;

a monitoring device processor enclosed within the housing;

a sensor coupled to the monitoring device processor and adapted to provide an output signal as a function of a concentration of an analyte in the user; and

calculate an amount of the fluid to be infused into the user's body based upon the output signal; and

cause the monitoring device communication circuit to transmit a first set of data for reception by the infusion device, the first set of data being indicative of the amount of the fluid to be infused and adapted to cause the infusion device to infuse the amount of the fluid into the body of the user.

42. The monitoring device of claim 41, wherein the monitoring device is a blood glucose test strip monitor, and wherein the medication infusion device is an insulin infusion pump.

43. The monitoring device of claim 42, wherein the monitoring device communication circuit includes one of a transmitter and a transceiver.

44. The monitoring device of claim 41, wherein the monitoring device further comprises an indicator coupled to the monitoring device processor and adapted to provide a notification of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

45. The monitoring device of claim 41, wherein the monitoring device further comprises an indicator coupled to the monitoring device processor and adapted to provide a notification of the completion of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

46. The monitoring device of claim 41, wherein the monitoring device further comprises a user input device for inputting a command and wherein the monitoring device processor is adapted to cause the monitoring device communication circuit to transmit the first set of data in response to the command from the input device.

47. The monitoring device of claim 41 wherein the infusion device is adapted to be controlled by a command and wherein the monitoring device further comprises:

a user input device for inputting the command, wherein the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the command for reception by the infusion device.

48. The monitoring device of claim 47 wherein the user input device comprises one of a button, a touch screen, a voice-activated device, and a menu structure shown on a display panel that is navigated by a keypad.

49. A method of infusing a fluid into a body of a user comprising:

measuring an output signal produced by a sensor, said output signal being a function of a concentration of an analyte in the user;

calculating an amount of the fluid to be infused into the user's body based upon the output signal;

transmitting a first set of data with a first communication circuit enclosed within a first housing adapted to be carried by the user, said first set of data being indicative of the amount of the fluid;

receiving the first set of data with a second communication circuit enclosed within a second housing adapted to be carried by the user; and

activating a drive mechanism to infuse the fluid in accordance with the first set of data.

50. The method of claim 49, wherein the drive mechanism is activated automatically after receipt of the first set of data by the second communication circuit.

51. The method of claim 49, wherein the sensor is a blood glucose test strip monitor sensor, and wherein the drive mechanism is an insulin infusion pump drive mechanism.

52. The method of claim 51, wherein the first communication circuit includes one of a transmitter and a transceiver and wherein the second communication circuit includes one of a receiver and a transceiver.

53. The method of claim 49 further comprising the step of providing a notification of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the first communication circuit.

54. The method of claim 53 wherein the notification is provided using at least one one of a vibration alarm, a sound generation device, a panel adapted to display text, and a LED.

55. The method of claim 49 further comprising the step of providing a notification of the completion of at least one event of the group consisting of:

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the first communication circuit.

56. The method of claim 49 further comprising the step of inputting a command with a user input device, wherein the first set of data is transmitted in response to the command.

57. An infusion system for infusing a fluid into a body of a user, the infusion system comprising:

means for measuring an output signal as a function of a concentration of an analyte in the user;

means for transmitting data;

a first processor capable of communication with the measuring means and the transmitting means;

a first program logic executed by the first processor, comprising;

means for calculating an amount of the fluid to be infused into the user's body based upon the output signal; and

means for causing the transmitting means to transmit a first set of data indicative of the amount of the fluid;

means for receiving the first set of data;

means for applying pressure to the fluid;

a second processor capable of communication with the receiving means and the pressure applying means; and

a second program logic executed by the second processor, comprising;

means for causing the pressure applying means to apply pressure to the fluid in accordance with the first set of data.

58. The system of claim 57, wherein the means for causing the pressure applying means to apply pressure is for automatically applying the pressure after receipt of the first set of data by the receiving means.

59. The system of claim 57 further comprising means for providing a notification to the user, wherein the first processor is further capable of communication with the notification means;

and wherein the first program logic further comprises;

means for causing the notification means to notify the user of at least one event of the group consisting of;

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

60. The system of claim 57 further comprising means for providing a notification to the user, wherein the first processor is further capable of communication with the notification means;

and wherein the first program logic further comprises;

means for causing the notification means to notify the user of the completion of at least one event of the group consisting of;

the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the first set of data by the monitoring device communication circuit.

61. The system of claim 57 further comprising means for manually inputting a command, wherein the first processor is further capable of communication with the inputting means;

and wherein the means for causing the transmitting means to transmit the first set of data is for transmitting the first set of data in response to the command.

62. A medication infusion device for infusing a fluid into a body of a user and adapted for communications with a physiological monitoring device adapted to provide an output signal as a function of a concentration of an analyte in the user, calculate an amount of the fluid to be infused into the user's body based upon the output signal, and transmit a first set of data indicative of the amount of the fluid to be infused, the medication infusion device comprising:

means for receiving the first set of data from the monitoring device;

means for applying pressure to the fluid;

a processor capable of communication with the receiving means and the pressure applying means; and

program logic executed by the processor, said program logic comprising means for causing the pressure applying means to apply pressure to the fluid in accordance with the first set of data.

63. A physiological monitoring device adapted for communication with a medication infusion device for infusing a fluid into a body of a user, the physiological monitoring device comprising:

means for measuring an output signal as a function of a concentration of an analyte in the user;

means for transmitting data;

a processor capable of communication with the measuring means and the transmitting means; and

program logic executed by the processor, comprising;

means for calculating an amount of the fluid to be infused into the user's body based upon the output signal; and

means for causing the transmitting means to transmit a first set of data for reception by the infusion device, the first set of data being indicative of the amount of the fluid to be infused and adapted to cause the infusion device to infuse the amount of the fluid into the body of the user.

1 Specification

[0003] This invention relates generally to improvements in medical devices, such as patient physiological monitoring systems and medication infusion systems that are used for controlled delivery of medication to a user. More specifically, this invention relates to improved methods and apparatuses for calculating and communicating the quantity or bolus of medication that is to be delivered to the user.

[0004] 2. Background

[0005] People with Type 1 diabetes and some with Type 2 diabetes use insulin to control their blood glucose (BG) level. Typically, if a person's BG level is too high, he or she can inject a “bolus” (dose) of insulin to lower his/her BG level to a desired target level. Furthermore, he or she may inject a bolus of insulin in anticipation of ingesting carbohydrates, thus heading off a sharp rise in BG level.

[0006] Various calculations can be used to determine the amount of insulin to inject, and bolus estimation software is available for performing such calculations. These software programs can be used on an electronic computing device, such as a computer, the Internet, a personal digital assistant (PDA), or an insulin delivery device. Insulin delivery devices include infusion pumps, injection pens, and IV meters.

[0007] Some bolus estimation software takes into account an individual's current BG level. Presently, blood glucose can be measured using devices such as a test strip meter, a continuous glucose measurement system, a hospital hemocue, or an automated intermittent blood glucose measurement system. BG measurement devices use various methods, such as a sample of blood, a sensor in contact with a bodily fluid, an optical sensor, an enzymatic sensor, or a fluorescent sensor.

[0008] When the BG measurement device has generated a measurement, it is displayed on the device. Then the user may visually read the BG measurement and physically enter it into an electronic computing device to calculate a bolus estimate. Finally, once the bolus estimate is calculated, the user can inject the insulin bolus, or can program an insulin delivery device to deliver the bolus into his/her body.

[0009] Unfortunately, this process can be cumbersome and subject to transcribing errors—for example, the user may not accurately enter the BG measurement that is displayed on the BG measurement device into the electronic computing device. Thus if the BG measurement is not entered correctly, the bolus estimate may not be accurate. Furthermore, once the bolus estimation calculation is complete, the user may not accurately enter the bolus amount into a programmable infusion device, or the user may read the bolus amount incorrectly and inject the wrong amount of medication.

SUMMARY OF THE ILLUSTRATED EMBODIMENTS

[0010] A physiological monitoring device that conducts a bolus estimation calculation is provided. In one aspect, the monitoring device communicates a bolus amount resulting from the bolus estimation calculation to a medication infusion device, which delivers a bolus of medication to a user based on the communication from the monitoring device. The medication infusion device delivers the medication automatically after receiving the communication from the monitoring device.

[0011] In another aspect, the monitoring device comprises a processor and a sensor coupled to the processor and adapted to provide an output signal as a function of a concentration of an analyte in the user. A communication circuit is coupled to the processor. The processor is adapted to calculate an amount of the medication or fluid to be infused into the user's body based upon the sensor output signal, and to cause the monitoring device communication circuit to transmit a set of data indicative of the amount of the fluid to be infused.

[0012] An indicator is coupled to the monitoring device processor and adapted to provide a notification of the following events: the measuring of the output signal produced by the sensor, the calculating of the amount of the fluid, and the transmitting of the set of data by the first communication circuit.

[0013] The medication infusion device comprises a processor and a drive mechanism coupled to the processor and adapted to infuse the fluid into the user's body. A communication circuit is coupled to the processor and adapted to receive the set of data from the monitoring device communication circuit. The processor is adapted to cause the drive mechanism to automatically infuse the fluid into the user in accordance with the set of data.

[0014] In another aspect, the monitoring device communication circuit is a transmitter or a transceiver, and the infusion device communication circuit is a receiver or a transceiver.

[0015] In an alternative embodiment, the monitoring device further comprises a user input device for inputting commands. The monitoring device communication circuit transmits the first set of data in response to a command from the input device.

[0016] In another aspect, the monitoring device processor is further adapted to determine a first amount of time that has elapsed since the sensor provided the output signal and to cause the monitoring device communication circuit to transmit the first set of data if the first amount of time does not exceed a predetermined amount of time.

[0017] In yet another embodiment, the monitoring device further comprises an indicator coupled to the monitoring device processor and adapted to provide a display of the amount of the fluid and a user input device for inputting commands. The monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit the first set of data in response to a first command from the input device.

[0018] In another aspect, the infusion device further comprises a user input device for inputting commands and an indicator coupled to the infusion device processor and adapted to provide a display of the amount of the fluid. An infusion device memory is coupled to the infusion device processor and adapted to store at least two fluid infusion parameters. The infusion device processor is further adapted to retrieve one of the fluid infusion parameters from the memory in response to a command from the input device associated with a selection by the user. The infusion device processor further causes the drive mechanism to infuse the fluid into the user's body in accordance with the first or second fluid infusion parameter.

[0019] In an alternative embodiment, the monitoring device processor is further adapted to cause the monitoring device communication circuit to transmit a first command repeatedly for a plurality of transmissions and the infusion device communication circuit is further adapted to receive the first command. The infusion device processor is further adapted to cause power to the infusion device communication circuit to be cycled whereby the power is removed from the infusion device communication circuit for a first time period and is restored to the infusion device communication circuit for a second time period. The infusion device processor causes the power to the infusion device communication circuit to be restored and the power cycling to be discontinued if the first command has been received.

[0020] In yet another embodiment, the monitoring device sensor is coupled to the monitoring device processor and adapted to provide first and second output signals as a function of first and second quantities of an analyte in the user. The monitoring device processor is adapted to calculate a first amount of the fluid to be infused into the user's body based upon the first output signal and generate a first code associated with the first amount of the fluid. The processor then causes the monitoring device telemetry circuit to transmit a first plurality of transmissions wherein each of the first plurality of transmissions is comprised of a first set of data and the first code, the first set of data being indicative of the first amount of the fluid.

[0021] The monitoring device processor then calculates a second amount of the fluid to be infused into the user's body based upon the second output signal and generates a second code associated with the second amount of the fluid. The processor next causes the monitoring device telemetry circuit to transmit a second plurality of transmissions wherein each of said second plurality of transmissions is comprised of a second set of data and the second code, the second set of data being indicative of the second amount of the fluid.

[0022] The infusion device telemetry circuit is adapted to receive the first and second plurality of transmissions from the monitoring device telemetry circuit. The infusion device processor is adapted to store a first received code, said first received code being the first code or the second code as received from one of the first or second plurality of transmissions. The processor then compares a second received code with the first received code, where the second received code is another of the first or second codes as received from another of the first or second plurality of transmissions. The processor then causes the drive mechanism to apply pressure to the fluid in accordance with the second set of data if the second received code does not equal the first received code.

[0023] In one aspect, the first code is generated by incrementing a counter to provide a first counter value and the second code is generated by incrementing the counter to provide a second counter value. In another aspect, the first code corresponds to a first date and time and the second code corresponds to a second date and time.

[0024] There are additional aspects to the present inventions. It should therefore be understood that the preceding is merely a brief summary of some embodiments and aspects of the present inventions. Additional embodiments and aspects of the present inventions are referenced below. It should further be understood that numerous changes to the disclosed embodiments can be made without departing from the spirit or scope of the inventions. The preceding summary therefore is not meant to limit the scope of the inventions. Rather, the scope of the inventions is to be determined by appended claims and their equivalents.

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] <cross-reference>FIG. 1</cross-reference> is a perspective view of a blood glucose monitor and an infusion pump in accordance with an embodiment of the present invention.

[0026] <cross-reference>FIG. 2</cross-reference> is a simplified block diagram of an infusion pump in accordance with an embodiment of the present invention.

[0027] <cross-reference>FIG. 3</cross-reference><highlight><italic>a </italic></highlight>is a block diagram of an RF communication system in the infusion pump in accordance with an embodiment of the present invention.

[0028] <cross-reference>FIG. 3</cross-reference><highlight><italic>b </italic></highlight>is a block diagram of an RF communication system in the infusion pump in accordance with another embodiment of the present invention.

[0029] <cross-reference>FIG. 4</cross-reference><highlight><italic>a </italic></highlight>is a simplified block diagram of a blood glucose monitor in accordance with an embodiment of the present invention.

[0030] <cross-reference>FIG. 4</cross-reference><highlight><italic>b </italic></highlight>is a simplified block diagram of a blood glucose monitor in accordance with another embodiment of the present invention.

[0031] <cross-reference>FIG. 5</cross-reference> is a simplified block diagram of a blood glucose monitor in accordance with still another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0032] In the following description, reference is made to the accompanying drawings which form a part hereof and which illustrate several embodiments of the present invention. It is understood that other embodiments may be used and structural and operational changes may be made without departing from the scope of the present invention.

[0033] A physiological monitoring device that conducts a bolus estimation calculation is provided. In one aspect, the monitoring device communicates a bolus amount resulting from the bolus estimation calculation to a medication infusion device, which then delivers a bolus of medication to a user based on the communication from the monitoring device. The monitoring device may also be used to control other functions of the medication infusion device based on communications from the monitoring device.

[0034] Referring to <cross-reference>FIGS. 1 and 4</cross-reference><highlight><italic>a</italic></highlight>, the monitoring device is a BG test strip meter <highlight><bold>10</bold></highlight> and the medication infusion device is a medication infusion pump <highlight><bold>50</bold></highlight>, such as for example, an insulin infusion pump. The BG meter <highlight><bold>10</bold></highlight> receives a test strip <highlight><bold>12</bold></highlight> with a sample <highlight><bold>14</bold></highlight> of the user's blood and measures the user's BG level with a sensor. The BG meter <highlight><bold>10</bold></highlight> then calculates a bolus amount that is transmitted to the infusion pump <highlight><bold>50</bold></highlight>, for example, using a radio frequency (RF) transmitter or transceiver. The infusion pump <highlight><bold>50</bold></highlight> then delivers a bolus of medication to the user based on the bolus amount data received from the BG meter <highlight><bold>10</bold></highlight>. Transmission of the bolus amount from the BG meter <highlight><bold>10</bold></highlight> to the infusion pump <highlight><bold>50</bold></highlight> may eliminate user transcription errors and simplify the use of a bolus estimator.

[0035] In particular embodiments, the physiological monitoring device is the BG meter <highlight><bold>10</bold></highlight> which includes a test strip receptacle or port <highlight><bold>11</bold></highlight> for receiving and analyzing the test strip <highlight><bold>12</bold></highlight> with the sample <highlight><bold>14</bold></highlight> of the user's blood to obtain a BG measurement. In alternative embodiments, the monitoring device may be a continuous glucose measurement system, a hospital hemocue, or an automated intermittent blood glucose measurement system. For example, the monitoring device may generally be of the type or include features disclosed in U.S. Pat. No. 6,558,320, U.S. Patent Application Publication No. 20020002326, published on Jan. 3, 2003, and U.S. patent application Ser. No. 09/377,472 filed Aug. 19, 1999 and entitled “Telemetered Characteristic Monitor System and Method of Using the Same,” and Ser. No. 09/334,996 filed Jun. 17, 1999 and entitled “Characteristic Monitor with a Characteristic Meter and Method of Using the Same,” which are herein incorporated by reference. Moreover, the monitoring device may use other methods or sensors for measuring the user's BG level, such as a sensor in contact with a body fluid, an optical sensor, an enzymatic sensor, a fluorescent sensor, or a blood sample placed in a receptacle. Some monitoring devices are adapted to be carried by a user during his or her daily activities, and thus, may be implanted within the body of the user, or may be external to the user's body and hand-held, or held in a clothing pocket or attached to the body or clothing by straps, adhesives, fasteners, etc.

[0036] In further alternative embodiments, the monitoring device may use samples from body fluids other than blood, such as interstitial fluid, spinal fluid, saliva, urine, tears, or sweat. Other physiological determining or measuring devices may be used to determine or measure the concentrations or quantities of other characteristics, analytes, or agents in the user, such as hormones, cholesterol, medication concentrations, viral loads (e.g., HIV), lactose, oxygen, pH, heart rate, respiratory rate, etc. which may be used in a bolus estimation algorithm or may be used to identify an alarm condition or record an event.

[0037] Referring again to <cross-reference>FIGS. 1 and 4</cross-reference><highlight><italic>a</italic></highlight>, the BG meter <highlight><bold>10</bold></highlight> includes a bolus estimator <highlight><bold>64</bold></highlight> that is comprised of software algorithms. Once the BG meter <highlight><bold>10</bold></highlight> obtains a BG measurement, the bolus estimator <highlight><bold>64</bold></highlight> uses the measurement data to calculate a bolus amount. The bolus amount data is transmitted to the infusion pump <highlight><bold>50</bold></highlight> using a radio frequency (RF) transmitter <highlight><bold>15</bold></highlight>, as will be described below. Alternatively, the RF transmitter <highlight><bold>15</bold></highlight> may be replaced with an RF transceiver <highlight><bold>19</bold></highlight> (as shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (as shown in <cross-reference>FIG. 5</cross-reference>), and the bolus data may be transmitted to the infusion pump <highlight><bold>50</bold></highlight> using the RF transceiver <highlight><bold>19</bold></highlight> or <highlight><bold>36</bold></highlight>.

[0038] In the illustrated embodiment, the test strip port <highlight><bold>11</bold></highlight> and RF transmitter <highlight><bold>15</bold></highlight> are coupled to a processor <highlight><bold>17</bold></highlight>, which executes programs (including the bolus estimator <highlight><bold>64</bold></highlight>) and controls the BG meter <highlight><bold>10</bold></highlight>. The processor <highlight><bold>17</bold></highlight> is also connected to a memory <highlight><bold>30</bold></highlight> for storing programs, history data, user defined information and parameters. The BG meter <highlight><bold>10</bold></highlight> also includes an indicator or display <highlight><bold>16</bold></highlight> for providing notifications to the user of the BG measurement, bolus amount information, and messages, such as status, alarms or error messages. In particular embodiments, the display <highlight><bold>16</bold></highlight> includes a backlight for reading the display <highlight><bold>16</bold></highlight> in the dark.

[0039] The BG meter <highlight><bold>10</bold></highlight> includes user input devices comprising one or more housing buttons <highlight><bold>18</bold></highlight> and <highlight><bold>20</bold></highlight> for control of the meter <highlight><bold>10</bold></highlight>, such as turning it on or off, reviewing previous BG measurements or bolus amounts, transmitting bolus data to the infusion pump <highlight><bold>50</bold></highlight>, and turning off the transmitter <highlight><bold>15</bold></highlight> (or transceiver <highlight><bold>19</bold></highlight> (shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (shown in <cross-reference>FIG. 5</cross-reference>)) in the BG meter <highlight><bold>10</bold></highlight> so that it does not send bolus data to the infusion pump <highlight><bold>50</bold></highlight>.

[0040] The BG meter <highlight><bold>10</bold></highlight> further includes an additional user input device comprising a keypad <highlight><bold>28</bold></highlight> with one or more keypad buttons <highlight><bold>22</bold></highlight>, <highlight><bold>24</bold></highlight>, and <highlight><bold>26</bold></highlight> that are dedicated to remotely controlling the infusion pump <highlight><bold>50</bold></highlight>, for example, via the RF transmitter <highlight><bold>15</bold></highlight> (or RF transceiver <highlight><bold>19</bold></highlight> (as shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (as shown in <cross-reference>FIG. 5</cross-reference>)), as will be described below. The keypad buttons <highlight><bold>22</bold></highlight>, <highlight><bold>24</bold></highlight>, and <highlight><bold>26</bold></highlight> may also be used to transmit bolus data to the infusion pump <highlight><bold>50</bold></highlight> and are labeled ‘S’ for “suspend”, ‘B’ for “bolus”, and ‘ACT’ for “activate.”

[0041] In alternative embodiments, other quantities and arrangements of buttons may be included on the meter <highlight><bold>10</bold></highlight>, and the buttons may be labeled other than as illustrated in <cross-reference>FIG. 1</cross-reference>. Alternatively, the keypad buttons <highlight><bold>22</bold></highlight>, <highlight><bold>24</bold></highlight>, and <highlight><bold>26</bold></highlight> may be omitted, and the housing buttons <highlight><bold>18</bold></highlight> and <highlight><bold>20</bold></highlight> may be used to remotely control the infusion pump <highlight><bold>50</bold></highlight>. On the other hand, the housing buttons <highlight><bold>18</bold></highlight> and <highlight><bold>20</bold></highlight> may be omitted, and the keypad buttons <highlight><bold>22</bold></highlight>, <highlight><bold>24</bold></highlight>, and <highlight><bold>26</bold></highlight> may be used to operate the BG meter <highlight><bold>10</bold></highlight>. Additionally, the user may use other methods to input commands with the BG meter <highlight><bold>10</bold></highlight>, such as selecting a menu item, using the display <highlight><bold>16</bold></highlight> as a touch screen, or pressing multi-function keys.

[0042] In addition to transmitting the bolus amount data to the infusion pump <highlight><bold>50</bold></highlight>, the BG meter <highlight><bold>10</bold></highlight> also stores the BG measurement and bolus data in the memory <highlight><bold>30</bold></highlight> of the BG meter <highlight><bold>10</bold></highlight> for subsequent analysis and review. A history of alarms or error messages generated by the BG meter <highlight><bold>10</bold></highlight>, as well as remote control commands sent to or information received from the infusion pump <highlight><bold>50</bold></highlight>, may also be stored in the memory <highlight><bold>30</bold></highlight>. Further, the user may periodically cause the BG meter <highlight><bold>10</bold></highlight> to download the stored data through a communication circuit (such as the RF transmitter <highlight><bold>15</bold></highlight> (or RF transceiver <highlight><bold>19</bold></highlight> (as shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (as shown in <cross-reference>FIG. 5</cross-reference>)), a cable, or a communication station), directly to a computer <highlight><bold>34</bold></highlight>, or alternatively, over the Internet to a remote server for storage. For example, a connector <highlight><bold>32</bold></highlight> may be inserted into the test strip port <highlight><bold>11</bold></highlight> to provide a wired connection to a USB, serial, or other port of the computer <highlight><bold>34</bold></highlight>, and data may be downloaded from the BG meter <highlight><bold>10</bold></highlight> through the connector <highlight><bold>32</bold></highlight> to the computer <highlight><bold>34</bold></highlight>. The user or a caregiver (e.g., the user's parent, health care professional, educator) can evaluate the user's therapy by accessing the historical BG measurements or bolus data downloaded from the meter <highlight><bold>10</bold></highlight>.

[0043] Referring now to <cross-reference>FIGS. 1 and 2</cross-reference>, the infusion pump <highlight><bold>50</bold></highlight> regulates the flow of fluid from the pump, through flexible tubing <highlight><bold>54</bold></highlight>, and into an infusion set <highlight><bold>56</bold></highlight> that is adhered to the user. Infusion sets that may be used as part of an infusion device are described in, but not limited to, U.S. Pat. Nos. 4,723,947; 4,755,173; 5,176,662; 5,584,813; and 6,056,718, which are herein incorporated by reference. The infusion pump <highlight><bold>50</bold></highlight> may be of the type described in U.S. Pat. Nos. 4,562,751; 4,685,903; 5,080,653; 5,097,122; 5,505,709; 6,248,093; and 6,554,798, which are herein incorporated by reference. Some infusion pumps are adapted to be carried by a user during his or her daily activities, and thus, may be implanted within the body of the user, or may be external to the body of the user and hand-held or held in a clothing pocket or attached to the body or clothing by straps, adhesives, fasteners, etc.

[0044] In alternative embodiments, other devices may be used for delivery or infusion of fluid into a user's body, such as for example, an implantable insulin infusion pump or a system that uses a combination of implantable and external components, an injection pen, an IV meter, etc.

[0045] Referring still to <cross-reference>FIGS. 1 and 2</cross-reference>, the infusion pump <highlight><bold>50</bold></highlight> includes an RF communication system <highlight><bold>60</bold></highlight> that in turn includes an RF receiver <highlight><bold>80</bold></highlight>, as shown in <cross-reference>FIG. 3</cross-reference><highlight><italic>a</italic></highlight>. This allows one-way communication from the BG meter <highlight><bold>10</bold></highlight> (or other external devices such as a remote programmer) to the infusion pump <highlight><bold>50</bold></highlight>. Alternatively, the RF communication system <highlight><bold>60</bold></highlight>′ may include an RF transceiver <highlight><bold>81</bold></highlight>, as shown in <cross-reference>FIG. 3</cross-reference><highlight><italic>b</italic></highlight>, which allows two-way communication between the BG meter <highlight><bold>10</bold></highlight> and the infusion pump <highlight><bold>50</bold></highlight>.

[0046] The RF communication system <highlight><bold>60</bold></highlight> communicates with a processor <highlight><bold>64</bold></highlight> contained in a housing <highlight><bold>52</bold></highlight> of the infusion pump <highlight><bold>50</bold></highlight>. The processor <highlight><bold>64</bold></highlight> is used to execute programs and control the infusion pump <highlight><bold>50</bold></highlight>, and is connected to an internal memory device <highlight><bold>66</bold></highlight> that stores programs, history data, user defined information and parameters. The memory device <highlight><bold>66</bold></highlight> is a ROM and DRAM, but alternatively, the memory device <highlight><bold>66</bold></highlight> may include other memory storage devices, such as RAM, EPROM, dynamic storage such as flash memory, energy efficient hard-drive, etc.

[0047] The infusion pump <highlight><bold>50</bold></highlight> is preferably programmed through a user input device comprising a keypad <highlight><bold>58</bold></highlight> on the housing <highlight><bold>52</bold></highlight>, or alternatively, by commands received from an RF programmer (not shown) through the RF communication system <highlight><bold>60</bold></highlight>. The infusion pump <highlight><bold>50</bold></highlight> may also be programmed by commands that are input using the keypad <highlight><bold>28</bold></highlight> on the BG meter <highlight><bold>10</bold></highlight> and received from the BG meter <highlight><bold>10</bold></highlight>, for example, through the RF communication system <highlight><bold>60</bold></highlight>, as will be described below. Feedback by the infusion pump <highlight><bold>50</bold></highlight> on status or programming changes is shown on a display <highlight><bold>68</bold></highlight>, is provided tactilely with a vibration alarm <highlight><bold>78</bold></highlight> or audibly through a speaker <highlight><bold>70</bold></highlight> or other sound generation device. The infusion pump <highlight><bold>50</bold></highlight> may also provide the user with either an audible alarm or a vibration alarm for notification of a low medication reservoir condition or low battery charge. Alarms may start out at a low decibel or vibration level and escalate until acknowledged by the user. In alternative embodiments, the keypad <highlight><bold>58</bold></highlight> may include other quantities and arrangements of keys than those illustrated in <cross-reference>FIG. 1</cross-reference>. Alternatively, the keypad <highlight><bold>58</bold></highlight> may be omitted, and the display <highlight><bold>68</bold></highlight> may be used as a touch screen input device. In further alternative embodiments, the keypad <highlight><bold>58</bold></highlight>, display <highlight><bold>68</bold></highlight>, and/or speaker <highlight><bold>70</bold></highlight> may be omitted, and some or all programming and data transfer may be handled through a communication circuit, i.e. the RF communication system <highlight><bold>60</bold></highlight>.

[0048] The processor <highlight><bold>64</bold></highlight> is also coupled to a drive mechanism <highlight><bold>72</bold></highlight> that is connected to a fluid reservoir <highlight><bold>74</bold></highlight> containing fluid. The processor <highlight><bold>64</bold></highlight> causes the drive mechanism <highlight><bold>72</bold></highlight> to deliver the fluid through an outlet <highlight><bold>76</bold></highlight> in the reservoir <highlight><bold>74</bold></highlight> and housing <highlight><bold>52</bold></highlight>, and then into the user's body through the tubing <highlight><bold>54</bold></highlight> and the infusion set <highlight><bold>56</bold></highlight>.

[0049] In particular embodiments, one-way communication is provided from the BG meter <highlight><bold>10</bold></highlight> to the infusion pump <highlight><bold>50</bold></highlight>. The BG meter <highlight><bold>10</bold></highlight> includes the RF transmitter <highlight><bold>15</bold></highlight> (shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>a</italic></highlight>), and the infusion pump <highlight><bold>50</bold></highlight> includes an RF receiver <highlight><bold>80</bold></highlight> (shown in <cross-reference>FIG. 3</cross-reference><highlight><italic>a</italic></highlight>). Alternatively, two-way communication may be provided between the BG meter <highlight><bold>10</bold></highlight> and the infusion pump <highlight><bold>50</bold></highlight>. The RF transmitter <highlight><bold>15</bold></highlight> in the BG meter <highlight><bold>10</bold></highlight> is replaced with an RF transceiver <highlight><bold>19</bold></highlight> (shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (shown in <cross-reference>FIG. 5</cross-reference>), and the RF receiver <highlight><bold>80</bold></highlight> in the infusion pump <highlight><bold>50</bold></highlight> is replaced with an RF transceiver <highlight><bold>81</bold></highlight> (shown in <cross-reference>FIG. 3</cross-reference><highlight><italic>b</italic></highlight>).

[0050] The infusion pump <highlight><bold>50</bold></highlight> provides several programming options, including remote and on-device programming. The infusion pump <highlight><bold>50</bold></highlight> also can be configured through a communication circuit, such as a cable or communication station, using a computer. Additionally, the infusion pump <highlight><bold>50</bold></highlight> allows the user to download information in the memory <highlight><bold>66</bold></highlight> through the communication circuit directly to a computer, or alternatively, over the Internet to a remote server for storage. Further description of a communication station of this general type may be found in U.S. Pat. No. 5,376,070, which is incorporated herein by reference. The user or a caregiver (e.g., the user's parent, health care professional, educator) can evaluate the user's therapy by accessing the historical BG measurements or bolus data downloaded from the BG meter <highlight><bold>10</bold></highlight> and insulin delivery information downloaded from the pump <highlight><bold>50</bold></highlight>.

[0051] Information may also be downloaded from the infusion pump <highlight><bold>50</bold></highlight> through the RF communication system <highlight><bold>60</bold></highlight>. Referring to <cross-reference>FIG. 3</cross-reference><highlight><italic>b</italic></highlight>, the RF communication system <highlight><bold>60</bold></highlight>′ may include a RF transceiver <highlight><bold>81</bold></highlight> for transmitting information to and receiving information from external devices. In particular embodiments, an external communication link (not shown) may be connected to a serial, USB, or other port of a computer. Information may be transmitted from the RF transceiver <highlight><bold>81</bold></highlight> in the infusion pump <highlight><bold>50</bold></highlight> to an RF transceiver in the external communication link (not shown), which then downloads the information through a wired connection to the computer. During the download process, the communication link may draw power from the computer through the serial, USB, or other port.

[0052] In other embodiments, the connector <highlight><bold>32</bold></highlight> may be inserted into the test strip port <highlight><bold>11</bold></highlight>′ of the BG meter <highlight><bold>10</bold></highlight>′ to provide a wired connection to a USB, serial, or other port of the computer <highlight><bold>34</bold></highlight>, as shown in <cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>. Information may be transmitted from the RF transceiver <highlight><bold>81</bold></highlight> in the infusion pump <highlight><bold>50</bold></highlight> to the RF transceiver <highlight><bold>19</bold></highlight> in the BG meter <highlight><bold>10</bold></highlight>′, and may then be downloaded through the connector <highlight><bold>32</bold></highlight> to the computer <highlight><bold>34</bold></highlight>. The BG meter <highlight><bold>10</bold></highlight>′ merely functions as a “pass through” connection between the infusion pump <highlight><bold>50</bold></highlight> and the computer <highlight><bold>34</bold></highlight>. During the download process, power may be drawn from a power supply (not shown) for the BG meter <highlight><bold>10</bold></highlight>′ (e.g., a battery), or alternatively, from the USB, serial, or other port of the computer <highlight><bold>34</bold></highlight>.

[0053] Alternatively, information may be transmitted from the RF transceiver <highlight><bold>81</bold></highlight> in the infusion pump <highlight><bold>50</bold></highlight> to the RF transceiver <highlight><bold>36</bold></highlight> in the BG meter <highlight><bold>10</bold></highlight>″, as shown in <cross-reference>FIG. 5</cross-reference>. The information may be transmitted from the infusion pump <highlight><bold>50</bold></highlight> to the BG meter <highlight><bold>10</bold></highlight>″ at a rate higher than can be handled by the meter processor <highlight><bold>17</bold></highlight>″. Accordingly, the BG meter <highlight><bold>10</bold></highlight>″ includes a communications microcontroller or processor <highlight><bold>38</bold></highlight> with a higher processing speed (e.g., 10 MHz) than the meter processor <highlight><bold>17</bold></highlight>″ with a lower processing speed (e.g., 1-4 MHz). The transmitted information is first processed by the communications processor <highlight><bold>38</bold></highlight>, then processed by the meter processor <highlight><bold>17</bold></highlight>″, and finally downloaded through the connector <highlight><bold>32</bold></highlight> to the computer <highlight><bold>34</bold></highlight>. Again, the BG meter <highlight><bold>10</bold></highlight>″ merely functions as a “pass through” connection between the infusion pump <highlight><bold>50</bold></highlight> and the computer <highlight><bold>34</bold></highlight>. In alternative embodiments, information may be transmitted from the infusion pump <highlight><bold>50</bold></highlight> and stored in the memory <highlight><bold>30</bold></highlight>′ or <highlight><bold>30</bold></highlight>″ of the BG meter <highlight><bold>10</bold></highlight>′ or <highlight><bold>10</bold></highlight>″ for subsequent downloading from the BG meter <highlight><bold>10</bold></highlight>′ or <highlight><bold>10</bold></highlight>″ to the computer <highlight><bold>34</bold></highlight>. In further alternative embodiments, information may be transmitted from the infusion pump <highlight><bold>50</bold></highlight> through the BG meter to the computer <highlight><bold>34</bold></highlight> using other modes of communication, such as infrared, cable, ultrasonic, sonic, optical, etc.

[0054] As previously stated, the BG meter <highlight><bold>10</bold></highlight> analyzes the blood sample <highlight><bold>14</bold></highlight> on the test strip <highlight><bold>12</bold></highlight> to calculate a BG measurement. The BG meter <highlight><bold>10</bold></highlight> next calculates a bolus amount and communicates the bolus amount to the infusion pump <highlight><bold>50</bold></highlight>. The pump <highlight><bold>50</bold></highlight> then delivers a bolus of the medication into the user based on the bolus amount data received from the BG meter <highlight><bold>10</bold></highlight>. In particular embodiments, the BG meter <highlight><bold>10</bold></highlight> automatically communicates the bolus amount data to the pump <highlight><bold>50</bold></highlight> once the BG meter <highlight><bold>10</bold></highlight> calculates the bolus amount. Alternatively, the BG meter <highlight><bold>10</bold></highlight> communicates the bolus amount to the pump <highlight><bold>50</bold></highlight> upon removal of the test strip <highlight><bold>12</bold></highlight> from the BG meter <highlight><bold>10</bold></highlight>, or in response to an action by the user.

[0055] The BG meter <highlight><bold>10</bold></highlight> provides notification to the user of several events, including when it is analyzing a blood sample, calculating a bolus amount, and communicating with the pump <highlight><bold>50</bold></highlight>. In particular embodiments, the notification is provided as a status on the display <highlight><bold>16</bold></highlight>. In alternative embodiments, the status is communicated to the user in other ways, such as using one or more light emitting diodes, a vibrator or other tactile device, or one or more audible tones (generated by a speaker, a piezoelectric sound generator or other sound generating device). However, when the BG meter <highlight><bold>10</bold></highlight> provides continuous or automatic BG measurements, the user is not constantly notified of the status of the calculations and transmissions.

[0056] Optionally, the user can direct the BG meter <highlight><bold>10</bold></highlight> to calculate a bolus estimate amount and/or provide bolus data to the infusion pump <highlight><bold>50</bold></highlight>. User input devices and methods for inputting commands to cause a bolus estimation calculation to be conducted and to transmit bolus data to the infusion pump <highlight><bold>50</bold></highlight> include: pressing a button, activating a user interface, touching a screen, selecting a menu item, and entering information about a meal such as carbohydrates to be ingested. The BG meter <highlight><bold>10</bold></highlight> may also re-transmit the bolus amount data to the pump <highlight><bold>50</bold></highlight> in response to a user action such as pressing a button, selecting a menu item, holding down a button, aligning the BG meter <highlight><bold>10</bold></highlight> and infusion pump <highlight><bold>50</bold></highlight>, etc. Alternatively, the BG meter <highlight><bold>10</bold></highlight> may be notified by the infusion pump <highlight><bold>50</bold></highlight> to re-transmit the bolus amount data.

[0057] In particular embodiments, the BG meter <highlight><bold>10</bold></highlight> increments a counter each time a new bolus amount is calculated and communicated to the pump <highlight><bold>50</bold></highlight>. If a previously calculated and transmitted bolus amount is re-transmitted, then the BG meter <highlight><bold>10</bold></highlight> does not increment the counter. Each transmission from the BG meter <highlight><bold>10</bold></highlight> to the infusion pump <highlight><bold>50</bold></highlight> includes the bolus amount and the counter value. When the infusion pump <highlight><bold>50</bold></highlight> receives the transmission from the BG meter <highlight><bold>10</bold></highlight>, the pump compares the counter in the new transmission to the counter in a previous transmission. If the counter has not incremented, the infusion pump <highlight><bold>50</bold></highlight> will ignore the new transmission since it is a duplicate of a previously-received communication. Thus, the infusion pump <highlight><bold>50</bold></highlight> will activate an insulin delivery only once for each calculated bolus amount.

[0058] In alternative embodiments, the BG meter <highlight><bold>10</bold></highlight> generates a unique code associated with each bolus amount that is communicated to the pump <highlight><bold>50</bold></highlight>. Each transmission from the BG meter <highlight><bold>10</bold></highlight> to the pump <highlight><bold>50</bold></highlight> includes the bolus amount and the unique code. The infusion pump <highlight><bold>50</bold></highlight> stores each code received and ignores any later transmission containing a code that was previously received. In one aspect, the BG meter <highlight><bold>10</bold></highlight> includes a clock circuit adapted to provide a date and time that may be used to generate the code, or alternatively, the date and time may be used as a counter.

[0059] In some embodiments, the BG meter <highlight><bold>10</bold></highlight> keeps track of the elapsed time between the point when a BG measurement is obtained and when a bolus amount is communicated to the infusion pump <highlight><bold>50</bold></highlight>. The infusion pump <highlight><bold>50</bold></highlight> includes a clock circuit adapted to provide a date and time, and thus the pump <highlight><bold>50</bold></highlight> only delivers medication in a bolus amount received from the BG meter <highlight><bold>10</bold></highlight> if the BG measurement used in the bolus estimation calculation is sufficiently recent in time. Bolus estimations can be at least partially dependent on the difference between the user's present blood glucose level and a desired target blood glucose level. Since a user's BG level varies over time, using a bolus estimation based on an old BG measurement might be inappropriate for the user.

[0060] A bolus estimation is expired (and will not be used for delivering medication to a user) when the BG measurement is too old to be considered representative of the user's present BG level. Thus the BG meter <highlight><bold>10</bold></highlight> will not transmit a bolus amount to the infusion pump <highlight><bold>50</bold></highlight> if 10 minutes or more have elapsed since the BG measurement was taken. Alternative shorter or longer time delays may be used, however, such as 7 minutes, 5 minutes, 4 minutes, 3 minutes, or 2 minutes, etc., as well as 12 minutes, 15 minutes, 20 minutes, 30 minutes, 1 hour, 1½ hour, 2 hours, 2½ hours, 3hours, 3½ hours, 4 hours, etc. Alternatively, the time required for a BG measurement to expire may be set by the user, a caregiver, a physician, a parent, a guardian, etc. For example, a child's BG level may change more quickly than that of a heavy adult, so the BG meter <highlight><bold>10</bold></highlight> may be programmed so that BG measurements older than 5 minutes cannot be transmitted to another device. On the other hand, an adult might program the BG meter <highlight><bold>10</bold></highlight> so that BG measurements expire after 12 minutes.

[0061] Alternatively, the infusion pump <highlight><bold>50</bold></highlight> is programmed to not use a bolus amount if the BG measurement used in the bolus estimation calculation has expired. The infusion pump <highlight><bold>50</bold></highlight> keeps track of the elapsed time between the point when a new bolus amount is received from the BG meter <highlight><bold>10</bold></highlight> and when the bolus amount is used to activate an insulin delivery. For example, the infusion pump <highlight><bold>50</bold></highlight> may be provided the age of the bolus amount it receives. In other words, the elapsed time between when a BG measurement is collected and when the bolus amount is communicated to the infusion pump <highlight><bold>50</bold></highlight> is transmitted along with each set of bolus data. The pump then can calculate the current age of the bolus amount by adding the age of the bolus amount at the time it was communicated to the time that has passed since the bolus amount was received. Thus, since the infusion pump <highlight><bold>50</bold></highlight> knows the age of the bolus amount, the infusion pump <highlight><bold>50</bold></highlight> can reject bolus amounts that are expired. Alternatively, the infusion pump <highlight><bold>50</bold></highlight> notifies the user if a bolus amount has been received but is expired, before the bolus amount is used to activate a medication delivery. The user may then choose to suspend or activate the bolus delivery.

[0062] In particular embodiments, the infusion pump processor <highlight><bold>64</bold></highlight> causes the drive mechanism <highlight><bold>72</bold></highlight> to deliver or infuse the fluid into the body of the user according to fluid infusion parameters. For example, the pump can deliver the medication in virtually a single dose, i.e., a “normal bolus.” Several minutes may be required to deliver the entire bolus amount depending on other fluid infusion parameters, such as the present basal rate that medication is being delivered, the size of the bolus amount, the delivery location on or in the body, and the maximum rate that the infusion pump <highlight><bold>50</bold></highlight> can deliver the medication, etc.

[0063] The user alternatively may program a bolus type other than a normal bolus. Other delivery profiles or bolus types can include a SQUARE WAVE™ bolus and a DUAL WAVE™ bolus. When a SQUARE WAVE™ bolus is used, the delivery of the bolus is spread at a constant rate over a time period. When a DUAL WAVE™ bolus is used, the user specifies a portion of the bolus amount to be delivered as a normal bolus, and the remaining portion to be delivered as a SQUARE WAVE™ bolus. Other bolus types or profiles can also be used to deliver the bolus amount.

[0064] Preferably, the infusion pump <highlight><bold>50</bold></highlight> automatically activates an insulin delivery almost immediately upon receiving a bolus amount communicated from the BG meter <highlight><bold>10</bold></highlight>, assuming the bolus amount has not expired. Alternatively, the bolus amount can be approved by the user before it is used. The bolus amount is displayed, and the user responds by pressing a button, selecting a menu item, touching a screen, etc., before the bolus amount is used for medication delivery. For example, the bolus amount may be displayed on the display <highlight><bold>16</bold></highlight> of the BG meter <highlight><bold>10</bold></highlight> and approved by the user before it is transmitted to the infusion pump <highlight><bold>50</bold></highlight>. Alternatively, the bolus amount may be displayed on the display <highlight><bold>68</bold></highlight> of the infusion pump <highlight><bold>50</bold></highlight> and approved by the user before the medication is delivered. Additionally, the user may indicate the bolus type before the bolus is delivered. For example, the user may employ the user input devices on the BG meter <highlight><bold>10</bold></highlight> to indicate the bolus type and any associated parameters (such as the bolus amount, the bolus delivery duration period, the portion of the bolus amount that is to be delivered immediately, the portion of the bolus amount that is to be delivered over the extended bolus delivery duration period, etc.) along with other parameters that are transmitted to the infusion pump <highlight><bold>50</bold></highlight> when a bolus amount is to be delivered. Alternatively, the user may use the infusion pump <highlight><bold>50</bold></highlight> to indicate the bolus type and any associated parameters. The bolus amount may be sent from the BG meter <highlight><bold>10</bold></highlight> to the infusion pump <highlight><bold>50</bold></highlight> automatically, whereupon the user input device on the pump <highlight><bold>50</bold></highlight> may be used to select a bolus type before the bolus is delivered. Additionally, the user can specify a default bolus type.

[0065] In some embodiments, the BG meter <highlight><bold>10</bold></highlight> transmits a bolus amount to the infusion pump <highlight><bold>50</bold></highlight> using radio frequency (RF) communication. Alternatively, other communication circuits are used, such as infrared (IR), wired, ultrasonic, sonic, optical, etc. Transmissions between the BG meter <highlight><bold>10</bold></highlight> and the infusion pump <highlight><bold>50</bold></highlight> may contain unique identifying information associated with the identity of the BG meter <highlight><bold>10</bold></highlight> and/or the infusion pump <highlight><bold>50</bold></highlight>, such as the BG meter's and/or the infusion pump's serial number, identification number, a password, a code, etc. The identification information may be used to discern between communications that are intended for the respective device (i.e., the BG meter <highlight><bold>10</bold></highlight> or the pump <highlight><bold>50</bold></highlight>), and those that are not. Alternative identification information or codes can include a password, a bit sequence, a special frequency, timing between communications, etc.

[0066] Preferably, the communication system in the BG meter <highlight><bold>10</bold></highlight> may be deactivated either automatically or by the user, whereupon the meter will not attempt to communicate with other devices. Thus when a new BG measurement is available, the BG meter <highlight><bold>10</bold></highlight> will not communicate a bolus amount to another device. For example, the RF transmitter <highlight><bold>15</bold></highlight> (<cross-reference>FIG. 4</cross-reference><highlight><italic>a</italic></highlight>) or the RF transceiver <highlight><bold>19</bold></highlight> (<cross-reference>FIG. 4</cross-reference><highlight><italic>b</italic></highlight>) or <highlight><bold>36</bold></highlight> (<cross-reference>FIG. 5</cross-reference>) can be deactivated and reactivated by the user. This can be useful, for example, if the BG meter <highlight><bold>10</bold></highlight> transmits at frequencies that might disrupt an airplane during take-off or landing. In alternative embodiments, other devices may be used to deactivate and reactivate the BG meter <highlight><bold>10</bold></highlight> communication system. For example, the infusion pump <highlight><bold>50</bold></highlight> can be used to deactivate the BG meter's communication system.

[0067] Additionally, the BG meter <highlight><bold>10</bold></highlight> can be programmed to reactivate the communication system after a pre-set duration. When the user deactivates the BG meter's communication system, the user is prompted to enter a duration of time for the communication system to remain deactivated. The communication system will automatically become active at the end of the time period. Alternatively, the user may specify a time of day for the communication system to become active. The user is alerted to review any bolus amounts that were generated while the communication system was deactivated. Then the user can request that they be sent to the infusion pump <highlight><bold>50</bold></highlight> if desired.

[0068] In accordance with one embodiment, two-way communication is used between the BG meter <highlight><bold>10</bold></highlight> and the infusion pump <highlight><bold>50</bold></highlight>. The infusion pump <highlight><bold>50</bold></highlight> sends an acknowledge (ACK) message to the BG meter <highlight><bold>10</bold></highlight> when it receives a transmission. In particular embodiments, the BG meter <highlight><bold>10</bold></highlight> will not re-transmit (even if requested by the user) if the BG meter <highlight><bold>10</bold></highlight> has received an ACK from the infusion pump <highlight><bold>50</bold></highlight>. Alternatively, the infusion pump <highlight><bold>50</bold></highlight> echoes the bolus amount back to the BG meter <highlight><bold>10</bold></highlight> and waits for a confirmation from the BG meter <highlight><bold>10</bold></highlight> before delivering the bolus amount. The user is alerted when communication between the BG meter <highlight><bold>10</bold></highlight> and infusion pump <highlight><bold>50</bold></highlight> is activated but not functioning properly.

[0069] The infusion pump <highlight><bold>50</bold></highlight> preferably uses power cycling to periodically supply power to its communication system <highlight><bold>60</bold></highlight>. The power cycle is the time period that the communication system <highlight><bold>60</bold></highlight> is off plus the time period that the communication system is on. In some embodiments, the power cycle is 8 seconds in length. Alternatively, shorter or longer power cycles may be used, such as 4 seconds, 2 seconds, or 1 second, etc., as well as 12 seconds, 15 seconds or 20 seconds, etc.

[0070] Additionally, the time period that the communication system <highlight><bold>60</bold></highlight> is on during each power cycle is preferably 48 milliseconds (ms). Alternatively, the period that the communication system is on during each power cycle can be greater or less than 48 ms, depending on the length of the message to be received, the communication frequency, the speed of the communication system electronics, etc. The BG meter <highlight><bold>10</bold></highlight> sends repeated signals to the infusion pump <highlight><bold>50</bold></highlight> for a period longer than the power cycle. Each signal sent from the BG meter <highlight><bold>10</bold></highlight> to the infusion pump <highlight><bold>50</bold></highlight> includes a command. The command is preferably short enough to be captured during the on-time of the infusion pump's <highlight><bold>50</bold></highlight> communication system <highlight><bold>60</bold></highlight>. In accordance with one embodiment, the command is short enough to be captured twice during the infusion pump's <highlight><bold>50</bold></highlight> communication system <highlight><bold>60</bold></highlight> on-time.

[0071] The time that the infusion pump's <highlight><bold>50</bold></highlight> communication system <highlight><bold>60</bold></highlight> must be on to capture the command from the BG meter <highlight><bold>10</bold></highlight> is short compared to the power cycle, or alternatively is short compared to a string of information. When the infusion pump <highlight><bold>50</bold></highlight> receives the command, the pump <highlight><bold>50</bold></highlight> stops power cycling its communication system <highlight><bold>60</bold></highlight> and turns the system <highlight><bold>60</bold></highlight> on continuously. Thus short commands may be used to activate the infusion pump's <highlight><bold>50</bold></highlight> communication system <highlight><bold>60</bold></highlight> so that one or more longer strings of information may be received by the pump <highlight><bold>50</bold></highlight>.

[0072] The infusion pump <highlight><bold>50</bold></highlight> prepares to receive a string of information that is longer than a command and includes a bolus amount. The string of information may further include an elapsed time since the BG measurement was taken, a bolus type, bolus parameters, a counter, a unique identification code, a date, a time, a serial number, and the time elapsed since the bolus amount was calculated, etc.

[0073] The BG meter <highlight><bold>10</bold></highlight> may transmit a date and time to the infusion pump <highlight><bold>50</bold></highlight> so that the pump <highlight><bold>50</bold></highlight> can determine the difference between the BG meter <highlight><bold>10</bold></highlight> date and time and the pump <highlight><bold>50</bold></highlight> date and time. Moreover, the pump <highlight><bold>50</bold></highlight> can reset its clock to correspond to the BG meter <highlight><bold>10</bold></highlight> clock. Alternatively, the BG meter <highlight><bold>10</bold></highlight> can use the infusion pump <highlight><bold>50</bold></highlight> date and time to reset the BG meter <highlight><bold>10</bold></highlight> clock. In particular embodiments, when the pump <highlight><bold>50</bold></highlight> acknowledges receipt of information from the BG meter <highlight><bold>10</bold></highlight>, the pump <highlight><bold>50</bold></highlight> will communicate its current time and date to the meter <highlight><bold>10</bold></highlight>. The meter <highlight><bold>10</bold></highlight> then resets its clock, if necessary, to correspond to the pump's clock.

[0074] The infusion pump <highlight><bold>50</bold></highlight> preferably returns to power cycling the communication system <highlight><bold>60</bold></highlight> after information has been received from the BG meter <highlight><bold>10</bold></highlight>. For example, power cycling may be restored after the pump <highlight><bold>50</bold></highlight> receives a complete signal containing a bolus amount from the BG meter <highlight><bold>10</bold></highlight>. Alternatively, the infusion pump <highlight><bold>50</bold></highlight> returns to power cycling at a predetermined period after the signal from the BG meter <highlight><bold>10</bold></highlight> has stopped, or after the commencement of a signal from the BG meter <highlight><bold>10</bold></highlight>.

[0075] In alternative embodiments there is no longer string of information that follows a command. Rather, the command itself includes all of the information to be sent to the pump, such as the bolus amount, the bolus type and/or a time parameter, serial number, BG meter counter, etc. Thus the pump does not change from its power cycling routine.

[0077] Alternative embodiments of a BG meter <highlight><bold>10</bold></highlight> include one or more indicators and user input devices, such as audible alarms, vibrators, displays (liquid crystal display (LCD), light emitting diodes (LEDs), touch screen, etc.), sound generation devices, keypads, keyboards, buttons, and voice activated controls, etc. In addition to the pump <highlight><bold>50</bold></highlight>, the BG meter <highlight><bold>10</bold></highlight> can communicate with other devices, such as a computer, PDA, telephone, central server, Internet hardware device, relay, remote alarm or notification device, and a remote controller, etc. The BG meter <highlight><bold>10</bold></highlight> uses one or more communication circuits or methods to communicate with these other devices, such as RF, infrared (IR), bluetooth, optical, sound, ultrasonic, and wired, etc.

[0078] The infusion pump <highlight><bold>50</bold></highlight> indicates its present function or activity, so that a user can monitor the pump's reaction to commands that it has received, for example, from the BG meter <highlight><bold>10</bold></highlight>. Also, the user may override commands that the infusion pump <highlight><bold>50</bold></highlight> has received from another device. Alternatively, the infusion pump <highlight><bold>50</bold></highlight> only communicates with a user through another device, such as via the BG meter <highlight><bold>10</bold></highlight>. Examples of functions/activities indicated to the user include: the delivery of a certain basal profile, the completion of delivery to the user of a certain portion of a bolus, the time period remaining for completing a bolus delivery, the suspension of pump <highlight><bold>50</bold></highlight> operations, the priming or seating of the pump <highlight><bold>50</bold></highlight>, etc. In one embodiment, the infusion pump <highlight><bold>50</bold></highlight> communicates to the BG meter <highlight><bold>10</bold></highlight> the pump status or alarms, such as a fluid path occlusion, an electrostatic discharge alarm, a low battery power level, a low reservoir level, etc.

[0079] The user accesses and implements commands using the BG meter <highlight><bold>10</bold></highlight> through a menu structure shown on the display <highlight><bold>16</bold></highlight> and navigated by the keypad <highlight><bold>28</bold></highlight>. Alternatively, input devices or other methods are used such as pressing dedicated keys, scribing a command on a screen, touching a touch screen, voice activated commands, etc. Each keystroke on the BG meter <highlight><bold>10</bold></highlight> is communicated to the infusion pump <highlight><bold>50</bold></highlight>. Alternatively, the BG meter <highlight><bold>10</bold></highlight> only communicates actionable commands to the infusion pump <highlight><bold>50</bold></highlight>. Thus, the user may press many keystrokes on the BG meter <highlight><bold>10</bold></highlight> before the BG meter <highlight><bold>10</bold></highlight> transmits to the pump <highlight><bold>50</bold></highlight>.

[0080] For example, the BG meter <highlight><bold>10</bold></highlight> does not communicate to the infusion pump <highlight><bold>50</bold></highlight> until the user has stopped pressing keys that might influence the infusion pump <highlight><bold>50</bold></highlight> function. Thus for example, the user might conduct a programming session on the BG meter <highlight><bold>10</bold></highlight> to implement a new basal delivery pattern, enter a new serial number of a new device that the infusion pump <highlight><bold>50</bold></highlight> should respond to, and program a bolus amount. The BG meter <highlight><bold>10</bold></highlight> would not initiate a transmission to the infusion pump <highlight><bold>50</bold></highlight> until the user has completed the programming session.

[0081] The BG meter <highlight><bold>10</bold></highlight> identifies the end of a programming session when the user inputs a completion command indicating that the session is complete or commanding the BG meter <highlight><bold>10</bold></highlight> to initiate the transmission. Alternatively, the BG meter <highlight><bold>10</bold></highlight> communicates at the end of each actionable command. Alternatively still, the BG meter <highlight><bold>10</bold></highlight> communicates to the infusion pump <highlight><bold>50</bold></highlight> whenever the user returns to the main menu, or the BG meter <highlight><bold>10</bold></highlight> waits a specified delay period after the last keystroke to determine that the user has completed the programming session. The specified delay period may be programmable, or may be a preset period such as 10 seconds, 15 seconds, 30 seconds, 1 minute, etc. The BG meter <highlight><bold>10</bold></highlight> nevertheless will communicate some commands immediately, such as for example, a suspend command (to stop medication delivery), responses to alarms, or starting a new bolus delivery.

[0082] In an alternative embodiment, the meter has a review feature so that the user may scroll through programming steps that are about to be sent to the pump. The user may choose to modify the commands or accept the commands before the meter initiates a transmission to the pump.

[0083] As described above, the infusion pump <highlight><bold>50</bold></highlight> communicates with various external devices, such as the BG meter <highlight><bold>10</bold></highlight>, using RF communication. Additionally, the infusion pump <highlight><bold>50</bold></highlight> uses power cycling to periodically supply power to its communication system <highlight><bold>60</bold></highlight>. Referring to <cross-reference>FIGS. 3</cross-reference><highlight><italic>a </italic></highlight>and <highlight><bold>3</bold></highlight><highlight><italic>b</italic></highlight>, to facilitate one-way RF communication, the infusion pump <highlight><bold>50</bold></highlight> includes a processor <highlight><bold>64</bold></highlight>, a RF receiver <highlight><bold>80</bold></highlight>, a RF microcontroller (or RF programmable integrated circuit—(RF PIC)) <highlight><bold>82</bold></highlight>, and an application specific integrated circuit (ASIC) <highlight><bold>84</bold></highlight>. Alternatively, to facilitate two-way RF communication, the RF receiver <highlight><bold>80</bold></highlight> may be replaced with an RF transceiver <highlight><bold>81</bold></highlight>, as shown in <cross-reference>FIG. 3</cross-reference><highlight><italic>b</italic></highlight>. The RF PIC <highlight><bold>82</bold></highlight> holds a 7-byte word, although in alternative embodiments, it may hold other lengths of data. The processor communicates with the RF PIC <highlight><bold>82</bold></highlight> and the ASIC <highlight><bold>84</bold></highlight> using synchronous peripheral interfaces (SPI interfaces).

[0084] The RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> receives and demodulates RF signals, extracts a data packet from the RF signal, and passes the data packet to the RF PIC <highlight><bold>82</bold></highlight>. The RF PIC <highlight><bold>82</bold></highlight> accepts and decodes the data packet and checks for format. If the format of the data packet is valid, the RF PIC <highlight><bold>82</bold></highlight> sends an interrupt signal to the ASIC <highlight><bold>84</bold></highlight>. When the ASIC <highlight><bold>84</bold></highlight> receives the interrupt signal from the RF PIC <highlight><bold>82</bold></highlight>, the ASIC <highlight><bold>84</bold></highlight> sends an interrupt to the processor <highlight><bold>64</bold></highlight>, triggering the processor <highlight><bold>64</bold></highlight> to notify the RF PIC <highlight><bold>82</bold></highlight> to pass the contents of its buffer to the processor <highlight><bold>64</bold></highlight>.

[0085] The processor <highlight><bold>64</bold></highlight> acquires the decoded data packet from the RF PIC <highlight><bold>82</bold></highlight> and evaluates the content, which may include a command or information to be stored. In response to some data packets, the processor <highlight><bold>64</bold></highlight> may send a command to the ASIC <highlight><bold>84</bold></highlight> to change the power conditions on the RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight>. The processor <highlight><bold>64</bold></highlight> also processes the commands and data received from the BG meter <highlight><bold>10</bold></highlight>, which may result in controlling functions on the infusion pump <highlight><bold>50</bold></highlight>. One of the main tasks for the ASIC <highlight><bold>84</bold></highlight> is to enable and disable power on the RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight>. Generally, the ASIC 84 cycles the power on the RF receiver <highlight><bold>80</bold></highlight> or the RF transceiver <highlight><bold>81</bold></highlight> to save energy. If commanded by the processor <highlight><bold>64</bold></highlight>, however, the ASIC <highlight><bold>84</bold></highlight> will enable the RF receiver <highlight><bold>80</bold></highlight> or the RF transceiver <highlight><bold>81</bold></highlight> to be powered continuously.

[0086] Each RF transmission sent to the infusion pump <highlight><bold>50</bold></highlight> preferably includes an RF signal header followed by a command packet or an information packet. Since the infusion pump's RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> is likely to wake up in the middle of a command packet, the RF signal header at the start of each transmission helps the infusion pump <highlight><bold>50</bold></highlight> to synchronize its data sampling and identify the first byte of a new command packet or information packet. The RF signal header is preferably the same for each transmission, and is transmitted at the start of each RF transmission.

[0087] The RF signal header may include two parts: a preamble and a start signature. The preamble is a series of pulses used to train the infusion pump's digital signal sampling, and allows the infusion pump <highlight><bold>50</bold></highlight> to synchronize its pulse sampling with the pulse bits in the new transmission. The start signature notifies the RF PIC <highlight><bold>82</bold></highlight> when the first byte of a new packet is starting. Alternatively, the RF signal header may include other data, or the RF signal header may be omitted.

[0088] The command packets are 7 bytes in length, and information packets are 71 bytes in length. Alternative embodiments incorporate command packets and information packets of different lengths. The last byte of every command or information packet is an 8-bit cyclic redundancy check (CRC) calculated on all the preceding bytes in the packet. Before a command or information packet is transmitted to the infusion pump <highlight><bold>50</bold></highlight>, it is preferably encoded by the BG meter <highlight><bold>10</bold></highlight> using a DC balanced encoding scheme, which translates 4 bits of data into 6 for transmission as follows:<table-cwu><number>1</number><table><tgroup><colspec></colspec><colspec></colspec><colspec></colspec><thead><row><entry></entry><entry></entry></row><row><entry></entry><entry></entry></row><row><entry></entry><entry>HEX</entry><entry>DC</entry></row><row><entry></entry><entry></entry></row></thead><tbody><row><entry></entry><entry>0</entry><entry>010101</entry></row><row><entry></entry><entry>1</entry><entry>110001</entry></row><row><entry></entry><entry>2</entry><entry>110010</entry></row><row><entry></entry><entry>3</entry><entry>100011</entry></row><row><entry></entry><entry>4</entry><entry>110100</entry></row><row><entry></entry><entry>5</entry><entry>100101</entry></row><row><entry></entry><entry>6</entry><entry>100110</entry></row><row><entry></entry><entry>7</entry><entry>010110</entry></row><row><entry></entry><entry>8</entry><entry>011010</entry></row><row><entry></entry><entry>9</entry><entry>011001</entry></row><row><entry></entry><entry>A</entry><entry>101010</entry></row><row><entry></entry><entry>B</entry><entry>001011</entry></row><row><entry></entry><entry>C</entry><entry>101100</entry></row><row><entry></entry><entry>D</entry><entry>001101</entry></row><row><entry></entry><entry>E</entry><entry>001110</entry></row><row><entry></entry><entry>F</entry><entry>011100</entry></row><row><entry></entry><entry></entry></row></tbody></tgroup></table></table-cwu>

[0089] The result of the encoding is that the 7-byte command packets require transmission of 11 bytes and the 71-byte information packets require transmission of 107 bytes. Upon receipt of the 11-byte or 107-byte packets from the BG meter <highlight><bold>10</bold></highlight>, the RF PIC <highlight><bold>82</bold></highlight> in the infusion pump <highlight><bold>50</bold></highlight> decodes the packet into the 7-byte command packet or the 71-byte information packet. The processor <highlight><bold>64</bold></highlight> checks all packets for valid identification of the infusion pump <highlight><bold>50</bold></highlight> (e.g., identification or serial number) and CRC. If the infusion pump <highlight><bold>50</bold></highlight> identification is not valid, the packet is ignored. If the CRC of the first command packet is not valid, the command is ignored. Otherwise, the processor <highlight><bold>64</bold></highlight> may send a negative acknowledge (NAK) response to any packet with an invalid CRC.

[0090] Information packets (71 bytes) are much larger than command packets (7 bytes), and cannot be stored in the RF PIC <highlight><bold>82</bold></highlight>, and thus, cannot be used to “wake up” the pump. Instead, a command packet must be sent to the infusion pump <highlight><bold>50</bold></highlight> to turn on the pump's RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> and prepare the pump <highlight><bold>50</bold></highlight> to receive an information packet. While power to the pump's RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> is being cycled, a command packet is repeatedly transmitted from the meter <highlight><bold>10</bold></highlight> to the pump <highlight><bold>50</bold></highlight> to activate the pump's RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight>. If an RF signal (i.e. including the first command packet) is present when the pump's RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> comes on, the pump <highlight><bold>50</bold></highlight> will attempt to store the contents of the signal in the RF PIC <highlight><bold>82</bold></highlight>.

[0091] The processor <highlight><bold>64</bold></highlight> will verify whether the content of the signal is a valid command packet. If the command packet is valid, then the infusion pump <highlight><bold>50</bold></highlight> will stop power cycling and power the RF receiver <highlight><bold>80</bold></highlight> and RF transceiver <highlight><bold>81</bold></highlight> continuously. Only the first command packet must be transmitted repeatedly. After the RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> is on full-time, other command packets or an information packet can be sent to the infusion pump <highlight><bold>50</bold></highlight>.

[0092] The pump <highlight><bold>50</bold></highlight> preferably recognizes two categories of command packets: remote control or normal bolus commands and bolus estimation or amount commands. Remote control or normal bolus commands directly control the pump's insulin bolus delivery. Bolus estimation or amount commands prepare the pump <highlight><bold>50</bold></highlight> to receive an information packet containing a new bolus estimate amount.

[0093] The pump <highlight><bold>50</bold></highlight> may receive a normal bolus command from the BG meter <highlight><bold>10</bold></highlight> or a remote programmer associated with the pump <highlight><bold>50</bold></highlight>. The bolus command preferably includes a type code indicating the type of device transmitting the message (e.g., the BG meter <highlight><bold>10</bold></highlight> or the remote programmer), unique identifying information about the pump <highlight><bold>50</bold></highlight> (e.g., serial number, identification number, password, or the like), a key code indicating which bolus command button has been pressed (e.g., button “S” <highlight><bold>22</bold></highlight>, button “B” <highlight><bold>24</bold></highlight>, or button “ACT” <highlight><bold>26</bold></highlight> on the BG meter <highlight><bold>10</bold></highlight>), and a counter indicating the number of times that the button has been pressed. In alternative embodiments, the bolus command may include other information and/or omit some of this data. When the pump <highlight><bold>50</bold></highlight> receives the bolus command, the processor <highlight><bold>64</bold></highlight> filters the command to discern the counter value so that the pump <highlight><bold>50</bold></highlight> can respond to the number of times the user has pressed the button to adjust a bolus.

[0094] The pump <highlight><bold>50</bold></highlight> may also receive a bolus estimation command from the BG meter <highlight><bold>10</bold></highlight>. The bolus estimation command is transmitted to the pump <highlight><bold>50</bold></highlight> to prepare the pump <highlight><bold>50</bold></highlight> to receive an information packet containing a new bolus estimate amount from the BG meter <highlight><bold>10</bold></highlight>. The bolus estimation command preferably includes a type code indicating the type of device transmitting the message (e.g., the BG meter <highlight><bold>10</bold></highlight>), unique identifying information about the pump <highlight><bold>50</bold></highlight> (e.g., serial number, identification number, password, or the like), and a key code indicating that a new bolus estimate amount is about to be transmitted. In alternative embodiments, the bolus estimation command may include other information and/or omit some of this data.

[0095] In response to RF transmissions, the pump <highlight><bold>50</bold></highlight> typically sends an acknowledge (ACK) response. However, in particular embodiments, the BG meter <highlight><bold>10</bold></highlight> does not include an RF receiver, and the pump <highlight><bold>50</bold></highlight> does not include an RF transmitter, and thus, the pump <highlight><bold>50</bold></highlight> does not send an ACK response if the type code in the command (e.g., bolus or BG measurement command) indicates that the device transmitting the message is the BG meter <highlight><bold>10</bold></highlight>. In alternative embodiments, both the BG meter <highlight><bold>10</bold></highlight> and the pump <highlight><bold>50</bold></highlight> may include an RF transceiver (i.e. transceiver <highlight><bold>19</bold></highlight> (shown in <cross-reference>FIG. 4</cross-reference>(<highlight><italic>b</italic></highlight>)) or <highlight><bold>36</bold></highlight> (shown in <cross-reference>FIG. 5</cross-reference>) in the BG meter <highlight><bold>10</bold></highlight>′ or <highlight><bold>10</bold></highlight>″, and transceiver <highlight><bold>81</bold></highlight> (shown in <cross-reference>FIG. 3</cross-reference>(<highlight><italic>b</italic></highlight>)) in the infusion pump <highlight><bold>50</bold></highlight>), and thus, the pump <highlight><bold>50</bold></highlight> may send an ACK response to the BG meter <highlight><bold>10</bold></highlight>.

[0096] When the infusion pump <highlight><bold>50</bold></highlight> receives a command packet from the BG meter <highlight><bold>10</bold></highlight>, the processor <highlight><bold>64</bold></highlight> will send a data packet through the ASIC <highlight><bold>84</bold></highlight>, commanding the RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> to remain on full-time for a specified number of minutes, to receive other command packets or an information packet. The RF receiver <highlight><bold>80</bold></highlight> or RF transceiver <highlight><bold>81</bold></highlight> may return to power cycling after the information packet has been received, a certain period of time after receiving a command (in the event that the anticipated information packet does not arrive), or after the battery in the infusion pump <highlight><bold>50</bold></highlight> has been removed and replaced.

[0097] In an alternative embodiment, the BG meter <highlight><bold>10</bold></highlight> transmits only normal bolus commands and does not transmit the bolus estimation or amount commands. However, the BG meter <highlight><bold>10</bold></highlight> transmits the normal bolus commands as a series of commands over a predetermined time period, and this collectively approximates a bolus estimation or amount. The BG meter <highlight><bold>10</bold></highlight> accomplishes this by converting bolus estimation data into the series of normal bolus commands. Thus by doing so, for example, the SQUARE WAVE™ bolus can be approximated by a series of normal bolus commands transmitted over a predetermined time period that corresponds to the SQUARE WAVE™ bolus time period.

[0098] Generally, the infusion pump's RF PIC <highlight><bold>82</bold></highlight> remains in receive mode unless it has received a command from the processor <highlight><bold>64</bold></highlight> to transmit, in which case it switches to transmit mode until the transmission is complete. Once the data has been transmitted, the RF PIC <highlight><bold>82</bold></highlight> automatically returns to receive mode.

[0099] Thus according to certain embodiments, there are disclosed methods and apparatuses relating to a physiological monitoring device that conducts a bolus estimation calculation. The monitoring device communicates a bolus amount resulting from the bolus estimation calculation to a medication infusion device, which delivers a bolus of medication to a user based on the communication from the monitoring device. The monitoring device may also be used to control other functions of the medication infusion device based on communications from the monitoring device.

[0100] While the description above refers to particular embodiments of the present invention, it will be understood that many modifications may be made without departing from the spirit thereof. The claims are intended to cover such modifications as would fall within the true scope and spirit of the present invention. The presently disclosed embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the claims rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.